Applications of nonparametric adaptive methods for simple reaction time experiments

Adaptive methods are commonly used in psychophysical research for detection and discrimination (see Leek, 2001; Treutwein, 1995, for reviews). In recent years, researchers have investigated via simulations some asymptotic and small-sample properties of two nonparametric adaptive methods—namely, the...

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Bibliographic Details
Published in:Attention, perception & psychophysics perception & psychophysics, 2009-10, Vol.71 (7), p.1664-1675
Main Authors: Hsu, Yung-Fong, Chen, Yen-Ho
Format: Article
Language:English
Subjects:
Activity levels. Psychomotricity
Algorithms
Behavioral Science and Psychology
Biological and medical sciences
Choice Behavior
Cognitive Psychology
Experiments
Fundamental and applied biological sciences. Psychology
Humans
Nonparametric Statistics
Psychology
Psychology. Psychoanalysis. Psychiatry
Psychology. Psychophysiology
Psychophysics
Reaction Time
Sample Size
Statistics, Nonparametric
Stochastic Processes
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Summary:Adaptive methods are commonly used in psychophysical research for detection and discrimination (see Leek, 2001; Treutwein, 1995, for reviews). In recent years, researchers have investigated via simulations some asymptotic and small-sample properties of two nonparametric adaptive methods—namely, the fixed-step-size up-down (García-Pérez, 1998, 2001) and the (accelerated) stochastic approximation (Faes et al., 2007). In the present article, we extend both methods to the simple reaction time (RT) situation for the measure of signal intensities that elicit certain (fixed) RT percentiles. We focus on extending the following four methods: the stochastic approximation of Robbins and Monro (1951), its accelerated version of Kesten (1958), the transformed up-down of Wetherill (1963), and the “biased coin design” of Durham and Flournoy (1994, 1995). In all simulations, we assume that the RT is Weibull distributed and that there is a linear relationship between the mean RT and its standard deviation. The convergences of the asymptotic and small-sample properties for different starting values, step sizes, and response criteria are systematically investigated.
ISSN:1943-3921
1943-393X
DOI:10.3758/APP.71.7.1664